A Conceptual Model to Quantify the Water Balance Components of a Watershed in a Continuous Permafrost Region

In regions characterized by continuous permafrost, hydrological modeling remains a complex activity, primarily due to constraints related to the prevailing climatic conditions and the specific behavior of the active layer. High-latitude regions receive less solar radiation; thus, most creeks are act...

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Bibliographic Details
Published in:Water
Main Authors: Alain Lubini Tshumuka, Musandji Fuamba
Format: Article in Journal/Newspaper
Language:English
Published: MDPI AG 2023
Subjects:
continuous permafrost
heat transfer
hydrological modeling
thaw depth
water balance
Hydraulic engineering
TC1-978
Water supply for domestic and industrial purposes
TD201-500
Nash
Sutcliffe
permafrost
Online Access:https://doi.org/10.3390/w16010083
https://doaj.org/article/cba7b1309a8d4c7da5dab6aedf60917c
Description
Summary:In regions characterized by continuous permafrost, hydrological modeling remains a complex activity, primarily due to constraints related to the prevailing climatic conditions and the specific behavior of the active layer. High-latitude regions receive less solar radiation; thus, most creeks are active only during summertime and stay frozen in the winter. To realistically simulate watersheds underlain by continuous permafrost, the heat transfer through the soil needs to be accounted for in the modeling process. In this study, a watershed located in a continuous permafrost zone in Russia is investigated. A model is proposed to integrate this heat transfer into an existing conceptual rain-flow transformation model, Hydrologiska Byråns Vattenbalansavdelning (HBV), to calculate the seasonal thaw depth and determine the components of water balance. The proposed integration is a novelty compared to the standard model, as it enables the physical and thermal properties of the soil to be taken into account. It was found that the proposed model, HBV-Heat, performs better than the stand-alone HBV model. Specifically, the average Nash–Sutcliffe efficiency (NSE) increases by 30% for the whole calibration period. In terms of the water balance components, the results are consistent with previous studies, showing that surface runoff represents 64% of the observed precipitation.

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